Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A method comprising: obtaining a precoder used to retransmit one codeword responsive to a known precoding matrix P of rank r and modulation and coding scheme MCS assignments used in an original transmission, and a desired retransmission rank r′; and scaling power in said retransmission responsive to at least three of 1) index of an uplink (UL) precoder used in a previous transmission, 2) rank r of an uplink (UL) precoder used in a previous transmission, 3) MCS assignments in a previous retransmission, 4) the desired transmission rank r′ used in a UL retransmission 5) the number of retransmit antennas x used for the codeword to be retransmitted in a previous transmission, 6) the number of retransmit antennas x′ used for the retransmission, 7) precoder used for a UL retransmission, 8) UL precoders and channel information for previous transmissions, and 9) latest channel measurements, wherein the method includes one of: a) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ=βr′/r, b) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βr′/r and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, c) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βr′/r and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, d) responsive to the number of retransmit antennas x used for the codeword to be retransmitted, index of precoder and MCS assignments in the previous retransmission, the number of transmit antennas x′ to be used for retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βx′/x and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, e) responsive to the number of retransmit antennas x used for the codeword to be retransmitted, MCS assignments in the previous retransmission, the number of transmit antennas x′ to be used for retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βx′/x and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, f) responsive to index of UL precoder, MCS assignments in the previous retransmission, and precoder for UL retransmission, determining a scaling factor θ and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, and g) responsive to the UL precoders and channel information for all previous transmissions, latest channel measurement, and precoder for UL retransmission, determining a scaling factor θ and resource blocks used for retransmission and scaling a retransmission of the codeword of transport blocks (TBs) in assigned resource blocks with the power in each antenna of the x′ antennas used for the retransmission with the factor θ.
A method for power scaling in uplink MIMO hybrid ARQ retransmissions involves obtaining a precoder for retransmitting a data block. This is based on the original transmission's precoding matrix (P with rank r) and modulation/coding scheme (MCS), along with the desired retransmission rank (r′). The power used in the retransmission is then adjusted based on at least three of the following: 1) UL precoder index from the previous transmission, 2) rank (r) of the previous UL precoder, 3) MCS assignments from the previous retransmission, 4) desired retransmission rank (r′), 5) number of retransmit antennas (x) used in the previous transmission, 6) number of antennas (x′) used in the retransmission, 7) the precoder used in the retransmission, 8) previous UL precoders and channel information, and 9) the latest channel measurements. A power scaling factor θ is calculated, which can be limited by upper and lower bounds.
2. The method of claim 1 , wherein, in step a), the parameter β or the factor θ is determined based on the signal-to-interference-plus-noise-ratio SINR and/or the MCS of each layer in a previous transmission and the SINRs and/or the MCSs for layers that are to be retransmitted which is obtained based on the precoder and MCS in the previous transmission and the precoder and MCS that are either preconfigured or determined by a base station to be used in a current retransmission.
In the power scaling method described previously, where a precoder is obtained for retransmitting a data block based on the original transmission's precoding matrix (P with rank r), modulation/coding scheme (MCS), and desired retransmission rank (r′); and the power used in the retransmission is adjusted based on at least three of several factors; the parameter β or the power scaling factor θ (used to scale the retransmission power in each antenna) is determined based on the signal-to-interference-plus-noise ratio (SINR) and/or the MCS of each layer in the previous transmission and the SINRs and/or MCSs for layers that are to be retransmitted. These retransmission SINRs/MCSs are based on the precoder and MCS in the previous transmission, as well as the precoder and MCS preconfigured or determined by a base station for the current retransmission.
3. The method of claim 1 , wherein, in step g), the factor θ is determined independently or jointly with the precoder for the retransmission based on the SINRs or the MCSs of each layer in previous transmissions and the SINRs and/or the MCSs for layers that are to be retransmitted which is obtained based on the precoder and MCS in the previous transmission and the precoder and MCS that are to be used in a current retransmission.
In the power scaling method described previously, where a precoder is obtained for retransmitting a data block based on the original transmission's precoding matrix (P with rank r), modulation/coding scheme (MCS), and desired retransmission rank (r′); and the power used in the retransmission is adjusted based on at least three of several factors; the scaling factor θ (used to scale the retransmission power in each antenna, calculated based on previous UL precoders and channel information, latest channel measurement, and the precoder for UL retransmission), is determined independently or jointly with the precoder for the retransmission based on the SINRs or the MCSs of each layer in previous transmissions and the SINRs and/or the MCSs for layers that are to be retransmitted. These retransmission SINRs/MCSs are obtained based on the precoder and MCS in the previous transmission and the precoder and MCS that are to be used in a current retransmission.
4. A method comprising: obtaining a precoder used to retransmit one codeword responsive to known precoding matrix P of rank r and modulation and coding scheme MCS assignments used in an original transmission, and a desired retransmission rank r′; forming an approximate channel covariance matrix; estimating a minimum mean square error receiver signal-to-interference-plus-noise-ratio (SINR) for each layer to be retransmitted responsive to said forming step; finding a precoding matrix from a precoding codebook that maximizes a sum-rate for enabling precoding selections for retransmissions in uplink multiple-input multiple-output MIMO hybrid automatic repeat request HARQ; and scaling power in said retransmission responsive to at least three of 1) index of an uplink (UL) precoder used in a previous transmission, 2) rank r of an uplink (UL) precoder used in a previous transmission, 3) MCS assignments in a previous retransmission, 4) the desired transmission rank r′ used in a UL retransmission 5) the number of retransmit antennas x used for the codeword to be retransmitted in a previous transmission, 6) the number of retransmit antennas x′ used for the retransmission, 7) precoder used for a UL retransmission, 8) UL precoders and channel information for previous transmissions, and 9) latest channel measurements, wherein the method includes one of: a) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ=βr′/r, b) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βr′/r and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, c) responsive to the index and rank r of the UL precoder, MCS assignments in the previous retransmission, and the rank r′ for UL retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βr′/r and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, d) responsive to the number of retransmit antennas x used for the codeword to be retransmitted, index of precoder and MCS assignments in the previous retransmission, the number of transmit antennas x′ to be used for retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βx′/x and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, e) responsive to the number of retransmit antennas x used for the codeword to be retransmitted, MCS assignments in the previous retransmission, the number of transmit antennas x′ to be used for retransmission, determining a parameter β used to perform the scaling power in the retransmission and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ=βx′/x and θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, f) responsive to index of UL precoder, MCS assignments in the previous retransmission, and precoder for UL retransmission, determining a scaling factor θ and scaling a retransmission power in each antenna of the x′ antennas used for the retransmission with a factor θ and/or min{θ MAX , θ} and/or max{θ MIN , θ}, where θ MAX and θ MIN are upper and lower bounds, respectively, on the scaling factor for the scaling power, and g) responsive to the UL precoders and channel information for all previous transmissions, latest channel measurement, and precoder for UL retransmission, determining a scaling factor θ and resource blocks used for retransmission and scaling a retransmission of the codeword of transport blocks (TBs) in assigned resource blocks with the power in each antenna of the x′ antennas used for the retransmission with the factor θ.
A method for power scaling in uplink MIMO hybrid ARQ retransmissions includes obtaining a precoder for retransmitting a data block, based on the original transmission's precoding matrix (P with rank r), modulation/coding scheme (MCS), and the desired retransmission rank (r′). An approximate channel covariance matrix is formed, and a minimum mean square error receiver signal-to-interference-plus-noise-ratio (SINR) is estimated for each layer to be retransmitted. A precoding matrix is selected from a codebook to maximize the sum-rate. The power used in the retransmission is adjusted based on at least three of the following: 1) UL precoder index from the previous transmission, 2) rank (r) of the previous UL precoder, 3) MCS assignments from the previous retransmission, 4) desired retransmission rank (r′), 5) number of retransmit antennas (x) used in the previous transmission, 6) number of antennas (x′) used in the retransmission, 7) the precoder used in the retransmission, 8) previous UL precoders and channel information, and 9) the latest channel measurements. A power scaling factor θ is calculated, which can be limited by upper and lower bounds.
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November 18, 2014
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